DE2720896C2 - Circuit for regulating the output frequency of a wobble oscillator - Google Patents

Description

The invention relates to a pouring arrangement loudly Preamble to the main claim.

A spectrum analyzer is used for evaluation of the frequency spectra shown, an exact assignment of the frequency of the wobble oscillator to the frequency scale the frequency coordinate of the display device is necessary. The respective position of the spectrum lengthways the frequency coordinate is essentially determined by the assignment of the frequency of the Wobbeloszillators for controlling wobble voltage and the associated deflection voltage of the Frequency coordinate of the display system. This assignment can be due to the most varied of influences be disturbed. In addition to the known technique of fading in frequency marks along the frequency coordinate it is known to automatically adjust the output frequency of the wobble oscillator by means of a correction voltage to regulate (DE-OS 20 49 969). The output frequency of the wobble oscillator is known in this Arrangement fed to a frequency discriminator, which is one of the intermediate frequency of the analyzer has a corresponding very stable center frequency. A switching device controlled by a wobble oscillator at the front the output voltage of this frequency discriminator becomes periodically during the return of the Wobbeis voltage fed as a correction voltage to the input of the voltage-controlled wobble oscillator, which simultaneously with a voltage is controlled which, without a correction voltage, corresponds to an intermediate frequency

Output frequency of the oscillator generated The output voltage of the frequency discriminator is integrated and it is thus generated a correction voltage for the wobble oscillator, by which the output frequency of the wobble oscillator exactly to the intermediate frequency determined by the frequency discriminator is regulated.

The correction of the output frequency of the wobble oscillator by one of the actual signal branch of the Analyzer separate correction branch cannot correct all frequency errors; also the accuracy, with which is the center frequency of the frequency discriminator is limited, especially since the frequency discriminator must have a relatively large bandwidth, which corresponds to the frequency deviation of the wobble oscillator.

In the case of an overlay receiver, it is already known to automatically retune the im Reception built-in electronically tunable filter an additional one from a wobble oscillator Provide tuned resonance circuit and the rectified output voltage of the swept Compare the resonance circuit in phase with the wobble voltage of the wobble oscillator and as a function to readjust both the resonance circuit and the Match the receiver's filter (DE-AS 15 41 612).

After all, it is already known to synchronize of two frequencies the instantaneous amplitudes of two voltages, one of which is a wobble voltage is to compare and to control a frequency generator depending on the amplitude difference (Soviet inventions illustrated. W 52, page 8. R 54 (26.6. 75)).

It is; The object of the invention is a simple structure To create a control circuit for a spectrum analyzer, with which the frequency scale of the spectral display automatically in very precise accordance with the given fixed frequency scale of the Display device is held.

This task is based on a circuit according to the preamble of the main claim by the characteristic features solved. Advantageous further developments result from the subclaims.

In the circuit according to the invention, all frequency errors occurring in the signal branch of the spectrum analyzer are eliminated without the aid of e ^; Corrected nes separate frequency discriminator, for example frequency errors that occur due to a further frequency conversion or due to misaligned resolution filters or due to signal transit times and time constants in the demodulator of the signal branch. With the circuit according to the invention, a higher accuracy with regard to the frequency readjustment can also be achieved than with the known circuit with a frequency discriminator, since the frequency of the auxiliary oscillator used in the invention and determining the accuracy can be realized with simple means much more precisely than the center frequency of a frequency discriminator.

The invention is illustrated below with the aid of a schematic Drawings of exemplary embodiments explained in more detail.

F i g. 1 shows the basic circuit diagram of a spectrum analyzer with a control circuit according to the invention. In the case of the spectral display, the frequency band to be displayed is fed in via input E , in the case of a conventional so-called intermediate frequency analyzer from an upstream tunable receiver. The switch 1, which is shown in dashed lines, is used to superimpose the input frequency ίε in a mixer 1 in a known manner with the wobble frequency / W of a wobble oscillator 3 and then evaluate in the intermediate frequency position in a subsequent analysis filter 4 and a demodulator 5 and finally as an amplitude value for the vertical deflection system y to a display device 6, for example a cathode ray tube. The frequency of the wobble oscillator 3 is tuned (wobbled) in a known manner via a wobble voltage generator 7. The wobble voltage is generally a symmetrical or asymmetrical sawtooth voltage, but it can also be any other periodic alternating voltage, for example a sinusoidal voltage. The wobble voltage is simultaneously fed to the horizontal deflection system χ of the display device. Via the wobble voltage generator 7, a control pulse R is also generated in a known manner during the return phase rder the wobble voltage, through which wel; The display was broken during the entire return, for example the beam is blanked in the case of a cathode ray tube. In this respect, the analyzer corresponds

a known device.

Gem.? According to the invention, a highly stable auxiliary oscillator 8, for example a quartz oscillator, is also provided, which supplies a fixed auxiliary frequency f _h and feeds this into the receiving branch of the analyzer in the fully drawn switch position of switch 1. The frequency f _h corresponds to a predetermined frequency value of the total frequency band to be displayed, which is at a predetermined point on the frequency scale 9 on the

J5 display device 6 is to be displayed. In the case of an IF analyzer, this predetermined point on the scale 9 is, for example, the center point M. which corresponds exactly to the selected intermediate frequency, and the auxiliary frequency h that is fed in also corresponds in this case to this intermediate frequency of the analyzer. However, the predetermined point could also be, for example, the left starting point of the frequency scale 9, and in this case the starting frequency of the to be swept over would then be

4> frequency band fed in as an auxiliary frequency.

The actual control loop is switched on at the output of the demodulator 5, namely the one that is demodulated The output signal is fed via a line 10 to a gate circuit 11, via the output of which a switch 12

is controlled in. When the switch 12 is closed, the currently prevailing amplitude of the wobble voltage of the generator 7, with which the wobble oscillator 3 is wobbled, is fed to a voltage comparator 13 effi Ii t, which compares this instantaneous voltage U _m with a reference voltage U _r and from this the difference voltage Ud bi. det, which is fed to a voltage summing element 14 in the exemplary embodiment shown. The switch 1, the gate circuit 11 and the auxiliary oscillator 8 are, as is indicated schematically.

each controlled via the return switching pulse R of the wobble voltage generator 7 so that the oscillator 8 only supplies its output frequency during the return period, the switch i assumes the switch position shown in full line and the gate circuit II also receives a signal for switching the switch via the line IO 12 lets through. The width of the pulse R generally corresponds to the total flyback time. If there are no major

are to be feared, this impulse could also be chosen to be narrower. If during this time of the pulse R the wobble oscillator 3 traverses the frequency band to be represented in the forward ν in the opposite direction, with the mostly faster return r, the fixed frequency component / λ is finally also reached and a steep, narrow output pulse / appears at the output of the demodulator 5, which over the Line 10 and the gate circuit 11, the switch 12 closes. So that the Wobbelspannungsgenerators 7 prevailing at that moment at the output 15 voltage Um corresponds exactly to the location of the frequency value f "along the frequency scale of the display device 9. Assuming that the frequency f " in the sense of the above example corresponds to the center frequency of the overall frequency band to be displayed, i.e. the intermediate frequency in an IF analyzer, this voltage U _m also corresponds directly to the center point M of the scale 9, without any error deviation. h_ if the pulse / appearing at the output of the demodulator were displayed on the display device 6 - which does not take place because of the blanking during the return movement - this pulse / would appear exactly at the center mark M of the scale 9. This instantaneous voltage value U _m is then compared in the comparator 13 with the reference _{voltage U r} , which corresponds to the nominal position, in the above example the center Λ / of the scale 9. If the pulse / occurs exactly at the point Λ / of the frequency scale 9 assigned to it , the voltages U _n , and U _{r are the} same. If, on the other hand, the pulse / deviates to the left or right from the center M , there is an inequality between these voltages, and a positive or negative differential voltage Ud is formed, which corresponds directly to the local deviation of this pulse / from the center M along the scale 9. If this differential voltage Ud is added to the actual Wobbeis voltage in the summing element 14, this deviation is automatically compensated for via the correcting frequency shift of the wobble oscillator 3 achieved therewith, ie it is regulated via the described control loop for equality between U, and U _m , and the pulse / thus always appears exactly at the mark M. If the spectrum to be analyzed at input E is then processed by the analyzer in the subsequent preliminary phase ν , the representation on the display device corresponds exactly to the frequency scale 9 recorded there, and the spectrum can be exactly reproduced by the user the frequency can be evaluated. The correction process described, "", must of course be retained until the next control process in the next return period, which can be done, for example, by known storage devices.

Instead of a correction of the wobble oscillator 3, a corresponding correction can optionally also be made via the deflection voltage fed to the horizontal deflection system χ of the display device 6 and corresponding to the frequency coordinate, as is done by the control line 16 and the voltage summing element 17 in FIG. 1 is indicated by dashed lines. The difference voltage Ud generated in the event of a deviation is then subordinated to the wobble voltage which is fed to the ^ deflection system, specifically in the sense of compensating for the deviation determined by this difference voltage Ud between the position of the pulses / and the assigned mark M. However, this possibility is less advantageous compared with the first-mentioned correction via the wobble oscillator 3, since the horizontal shift of the r-axis overwrites the screen on the one hand and does not write it out in full on the other.

The in F i g. The development shown in FIG. 2 is particularly advantageous when the Wobbe voltage of the generator 7 is controlled symmetrically to the voltage zero point to ίο positive and negative values, i.e. the voltage zero point corresponds to the center / V / of the frequency scale 9. The reference voltage U _r is thus also zero, and there is a very simple possibility for the voltage comparison and the generation of the differential voltage Uj. This is namely equal to the respectively determined instantaneous voltage value Um. This differential voltage can then be used again directly in the sense of the exemplary embodiment according to FIG.

FIG. 2 shows another control option for correcting the frequency of the wobble oscillator 3 and, above all, also for holding the correction voltage obtained until the next control process. The generated differential voltage Ud is fed to an integrator 18 and integrated there over several flyback periods r . The integrated correction voltage thus corresponding at the output of the integrator 18 then no longer corresponds directly to the deviation occurring in the frequency scale, but it is still proportional to this. This deviation can, however, be compensated for in a simple manner via the tuning gradient of the wobble oscillator 3, that is, two different control inputs are provided in the oscillator 3: the first control input 20 enables the wobble and control via the wobble voltage in the usual way, the other additional control input 19 leads to an additional tuning element detuning the frequency of the oscillator 3, the tuning gradient of which is greater than that of the first control input 20 the deviation corresponding to the differential voltage Ud along the frequency scale 9 is corrected. Of course, the one shown in FIG. The separate control of the oscillator 3 shown in FIG. 2 can also be used instead of the above-mentioned summation of the voltages in the summing element 14, in that the difference voltage Ud is fed directly to the control input 19 and is stored in each case via an additional circuit during a wobble voltage period. In this case, the tuning gradients of the two control inputs 19 and 20 would have to be the same, since the differential voltage Ud corresponds directly to the deviation error.In the latter case, it is therefore useful if both control inputs 19 and 20 act on one and the same tuning element, e.g. the opposite connections a conventional varactor diode are fed.

The auxiliary oscillator 8 does not necessarily have to be switched off during the lead-in period; but it is useful in order to avoid a disturbance of the spectrum to be displayed in the lead period and a crosstalk of this oscillator on the input E τα . This could also be done by improving the

Switch I can be avoided. Another possibility is 8 not to allow the oscillator swing fh on the lying directly in the displayed frequency band frequency but their image frequency, which for the above-described Nachstimmvorgang in ~ - is exploitable> same way as the frequency fh but by selective members can be kept away from input E. The non-linear converter properties of the analyzer could also be used to generate the frequency fh by feeding in a subharmonic of this frequency or the image frequency from the auxiliary oscillator 8, from which the desired frequency is then produced in the receiving channel.

The slope of the wobble voltage in the return phase r is usually greater than in analyzers of this type in the preliminary phase v, d. H. the rate of change of frequency in the return is greater than in the forward.

In addition, the AiiäiyäicmiicF bcSiiZi a ütivcimciuii- oscillator S GBC

be equal, which is added, for example, in addition in the summing element 14 or 17 or is introduced directly into the integrating member 18.

The described control circuit according to the invention can also be used for another purpose at the same time. If, for example, a certain frequency value is to be evaluated and analyzed on the display device 6, it is often useful if it always appears at a predetermined point of the horizontal deflection of the display device, i.e. if this frequency component does not move along the frequency scale in the event of any frequency changes in this frequency component. With the circuit shown, such a dominant frequency value can always be kept at a predetermined point on the frequency scale, for example again the center point M, in a simple manner, by opening the gate circuit 11 during the lead phase v, during which the i bh

signal propagation time, which is a fixed value at constant processing speed. These two variables can mean an additional frequency offset between forward and reverse, so the readjustment carried out during the reverse phase would not apply in the same way to the forward phase. This frequency deviation resulting from constant internal device properties can, however, be fed to the analyzer by an additional fixed correction direct voltage f _E, controlled via the control input 21 and so the control of the wobble oscillator 3 takes place on this selected frequency component, which then always like the pulse / again at the mark M. In this case it is expedient to also arrange a threshold value circuit in the control line 10, so that regulation can only be made to a frequency component of a predetermined amplitude.

1 sheet of drawings

Claims (11)

1 claims: 1. Circuit for regulating the output frequency of a wobble oscillator of a spectrum analyzer swept by means of a wobble voltage to a predetermined frequency value which corresponds to a predetermined point of the frequency coordinate of the display device, at which periodically, in particular during the flyback period of the wobble voltage, a correction voltage for the voltage-controlled wobble oscillator or for the deflection circuit generating the deflection voltage of the frequency coordinate of the display device, the size of which corresponds to a possible deviation of the predetermined frequency of the wobble oscillator from its target value, characterized by a highly constant auxiliary oscillator (8), which has an output frequency corresponding to the predetermined target frequency (ft) supplies, and which is switched on periodically, in particular during the flyback period (r) of the wobble voltage, to input (E) of the spectrum analyzer is Et, the output (10) of a demodulator (5) is connected to the Spektramanalysators with the voltage comparison and control circuit (10 to 18) in such a way that in each case at the time, in which, when auxiliary oscillator frequency (fi) of the demodulator (5 ) supplies an output pulse (I) , determines the instantaneous amplitude (U _n ) of the Wobbeis voltage and from this the correction voltage (U _n or Ud) is derived. 2. A circuit according to claim 1, characterized in that when ti s output pulse (I) of the demodulator (5) occurs, the instantaneous amplitude (Um) of the Wobbeis voltage is compared with a nominal voltage (Ur) which corresponds to the position of the predetermined point (M) corresponds to the frequency coordinate of the display device (6), and the difference (Ud) -to of these two voltages is used as the correction voltage. 3. A circuit according to claim 2, characterized in that the differential voltage (Ud) is stored during a wobble voltage period. 4. A circuit according to claim 2 or 3, characterized in that the differential voltage (UJ) is superimposed directly on the Wobbeis voltage supplied to the Wobbeioszillator (3) (summing element 14). 5. Circuit according to one of claims 2 to 4, characterized in that the differential voltage (Ud) is integrated in an integrating element (17). 6. Circuit according to one of the preceding claims for an analyzer whose wobble voltage is zero at the predetermined point of the frequency coordinate of the display device, characterized in that the instantaneous wobble voltage (Um) is used directly as a correction voltage. 7. Circuit according to one of the preceding claims, characterized in that the output voltage of the demodulator (5) is fed to the other components of the voltage comparison and control circuit (10 to 18) via a gate circuit (II), each of which is supplied together with the auxiliary oscillator (8 ), in particular during the return (r) of the wobble span generator (7), becomes effective. 8. Circuit according to one of the preceding claims, characterized in that the voltage comparison and control circuit comprises an electronic switch (12) closed in each case during the occurrence of the demodulator output pulse (I) , by means of which the torque amplitude (Un) that is present during the closing period Wobbeis voltage is scanned 9. Circuit according to one of the preceding claims, characterized in that the control of the wobble oscillator (3) via a control input (20) provided for the wobble voltage in addition to the control input (19) with compared to this control input (20) greater tuning slope depending on the integrated Correction voltage (Ud) takes place. 10. Circuit according to one of the preceding claims, characterized by an auxiliary oscillator (8) tuned to the image frequency of the predetermined frequency (ft,) or a subharmonic of this predetermined frequency or the image frequency. 11. Circuit according to one of the preceding claims, characterized in that the auxiliary oscillator (8) is switched on during the wobble voltage return (r) and that the voltage comparison and control circuit (10 to 18) is supplied with an additional correction voltage which is due to the different Frequency change speed of the wobble oscillator between forward and reverse and / or compensates for the frequency offset caused by the signal propagation time in the analysis filter (4)